Quantum Rings Launches an Open Quantum Platform to Remove Obstacles
Quantum Rings
Known for its cutting-edge quantum developer tools, Quantum Rings Inc. has formally introduced its Open Quantum platform, a project aimed at removing the technological and financial obstacles preventing the broad use of quantum computing. According to the statement, the new platform offers smooth, immediate cloud access to top quantum computers from several important suppliers. These suppliers consist of Rigetti, IQM, and IonQ.
The Open Quantum platform’s main objective is to democratize access, facilitate quick iteration, and assist the large-scale creation of sophisticated quantum algorithms and applications. The platform is especially made to close the critical gap between simulation capabilities and practical quantum computer operation at the highest level.
Quantum Rings has partnered with qBitTensor Labs to expedite adoption and experimentation right away. The companies are providing free quantum compute credits worth hundreds of thousands of dollars as a result of this partnership. These credits will be awarded on a first-come, first-served basis and are intended for public trials.
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Seamless Integration and No-Code Workflows
A key component of the new Open Quantum platform is its ease of use, which allows for integration into current developer workflows via two main interfaces.
First, a Python SDK that provides native interoperability with the popular open-source Qiskit framework is available to developers. This complete Qiskit compatibility guarantees simple process integration without requiring significant rework or upskilling. Additionally, the SDK works with a number of well-known Qiskit-based packages, including qiskit-finance.
Second, users can upload quantum circuits with ease the platform’s no-code online interface. Using this gateway, developers can get results from the actual quantum hardware in a matter of minutes. Major operating systems, such as Windows, macOS, and Linux, are compatible with the platform’s overall design.
According to CEO Bob Wold, the Open Quantum platform enables all researchers, engineers, and students who previously faced substantial budgetary barriers and proprietary interfaces to have access to high-fidelity quantum hardware. The Quantum Rings website provides access to the platform.
Leveraging High-Performance Simulation Expertise
Quantum Rings is renowned for its robust simulation environment, which makes it possible to run intricate quantum circuits on conventional hardware, such a laptop. This unique simulation SDK is thought to be the most sophisticated quantum simulator available, setting a new benchmark for developers. This feature makes it possible to thoroughly test and improve algorithms before putting them to use on real hardware.
The company specializes in providing these state-of-the-art simulation tools to researchers, businesses, and consultants. The Quantum Rings platform enables customers to scale up their challenges, whereas real quantum computers usually show significant error rates between 0.1% and 2.0% every operation. On their own computer, researchers can use the platform to address real-world issues that involve millions of gate operations and hundreds of logical qubits. State vector simulators, on the other hand, usually restrict local executions to roughly 35 qubits.
The remarkably high fidelity of the simulation technique is praised. It was demonstrated that the Quantum Rings simulator could run the largest and most intricate circuits from the 2019 Google Quantum Supremacy Experiment on a traditional computer with just 32 GB of RAM while maintaining an unprecedented level of accuracy, obtaining a Linear Cross Entropy (XEB) score of 0.622.
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Simulation: A Cost-Effective Path to Innovation
Using physical quantum computers to develop massive circuits frequently presents a number of difficulties, such as costly subscriptions, lengthy wait times, high expenses per usage, and high error rates. Even basic sample code can cost hundreds or thousands of dollars to execute, and access to physical quantum computing can cost $1.60 per second or more. Teams may be reluctant to test frequently and early due to these uncertain expenses.
On the other hand, there are no additional expenses or wait times when employing Quantum Rings to simulate on a user’s own infrastructure. According to the organization, this enables speedier learning and iteration, producing the best results sooner.
With free academic plans for use up to 128 qubits and free plans for other non-commercial applications up to 64 qubits, Quantum Rings is incredibly affordable. Because all subscriptions offer unlimited use and predictable rates, consumers can conduct experiments as frequently as they like without worrying about their expenses growing. “Perhaps the most advanced simulator on the market today, executing hundreds of qubits on your laptop,” is how Applied Quantum Software CEO Tom Finke described Quantum Rings. The director of ASU’s Computational Research Accelerator, Dr. Gil Speyer, expressed enthusiasm for the innovation that will result from researchers utilizing this capability on a large scale.
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